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##=============================================================================

##

##      platform.S

##

##      MIPS VRC4372 platform code

##

##=============================================================================

#####ECOSGPLCOPYRIGHTBEGIN####

## -------------------------------------------

## This file is part of eCos, the Embedded Configurable Operating System.

## Copyright (C) 1998, 1999, 2000, 2001, 2002 Red Hat, Inc.

##

## eCos is free software; you can redistribute it and/or modify it under

## the terms of the GNU General Public License as published by the Free

## Software Foundation; either version 2 or (at your option) any later version.

##

## eCos is distributed in the hope that it will be useful, but WITHOUT ANY

## WARRANTY; without even the implied warranty of MERCHANTABILITY or

## FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License

## for more details.

##

## You should have received a copy of the GNU General Public License along

## with eCos; if not, write to the Free Software Foundation, Inc.,

## 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA.

##

## As a special exception, if other files instantiate templates or use macros

## or inline functions from this file, or you compile this file and link it

## with other works to produce a work based on this file, this file does not

## by itself cause the resulting work to be covered by the GNU General Public

## License. However the source code for this file must still be made available

## in accordance with section (3) of the GNU General Public License.

##

## This exception does not invalidate any other reasons why a work based on

## this file might be covered by the GNU General Public License.

##

## Alternative licenses for eCos may be arranged by contacting Red Hat, Inc.

## at http://sources.redhat.com/ecos/ecos-license/

## -------------------------------------------

#####ECOSGPLCOPYRIGHTEND####

##=============================================================================

#######DESCRIPTIONBEGIN####

##

## Author(s):   nickg

## Contributors:        nickg

## Date:        1999-04-20

## Purpose:     MIPS vrc4372 platform code

## Description: Platform specific code for VRC4372 board.

##

##

##

##

######DESCRIPTIONEND####

##

##=============================================================================

#include 

#include 

#ifdef CYGPKG_KERNEL

# include 

#endif

#include 

##-----------------------------------------------------------------------------

## ISR springboard.

## This routine decodes the interrupt from the VRC4372 interrupt controller

## and vectors to it.

        # On entry:

        # a0 = MIPS status register interrupt number (1,2 or 3)

        # a1 = ISR data value (= interrupt status reg address)

        # a2 = saved reg dump ptr

        # s0 = saved reg dump ptr

        # s1 = vector table offset

        # s2 = interrupt number

        # a3,v0,v1 etc available for use

        .text

hal_isr_springboard:

        lw      v0,0(a1)                        # v0 = stat reg value

        # The following code implements an ls bit index algorithm similar

        # to that in hal_lsbit_index() in hal_misc.c.

        negu    v1,v0                           # v1 = -v0

        and     v1,v1,v0                        # v1 &= v0 [isolate ls bit]

        sll     v0,v1,16                        # v0 = v1<<16

        subu    v1,v0,v1                        # v1 = v0 - v1

        sll     a0,v1,6                         # a0 = v1<<6

        addu    v1,v1,a0                        # v1 += a0

        sll     a1,v1,4                         # a1 = v1<<4

        addu    v1,v1,a1                        # v1 += a1

        la      v0,hal_isr_springboard_table    # v0 = table address

        srl     v1,v1,26                        # v1 = v1>>26

        addu    v1,v1,v0                        # v1 = table entry address

        lb      a0,0(v1)                        # a0 = intc isr number

        addi    s2,a0,6                         # s2 = eCos isr number

        sll     s1,s2,2                         # s1 = isr table index

        la      v1,hal_interrupt_handlers

        addu    v1,v1,s1                        # v1 = isr handler address

        lw      v1,0(v1)                        # v1 = isr handler

        la      a1,hal_interrupt_data

        addu    a1,a1,s1                        # a1 = address of data ptr

        lw      a1,0(a1)                        # a1 = data pointer

        move    a0,s2                           # pass interrupt number

        jr      v1                              # jump to handler, return is to

                                                # default vsr already in ra

        nop

hal_isr_springboard_table:

        .byte  -1,  0,  1, 12,  2,  6,  0, 13

        .byte   3,  0,  7,  0,  0,  0,  0, 14

        .byte  10,  4,  0,  0,  8,  0,  0, 25

        .byte   0,  0,  0,  0,  0, 21, 27, 15

        .byte  31, 11,  5,  0,  0,  0,  0,  0

        .byte   9,  0,  0, 24,  0,  0, 20, 26

        .byte  30,  0,  0,  0,  0, 23,  0, 19

        .byte  29,  0, 22, 18, 28, 17, 16,  0

##-----------------------------------------------------------------------------

## Data Load/Store Bus error VSR

##

## If the VRC4373 tries to access a PCI config space register that does

## not have a real device behind it, it provokes a bus error.

## This is a special bus error VSR that detects when we get a bus error

## from a PCI configuration space access and fixes it up to allow the

## program to continue.

## This VSR works in conjunction with hal_pci_config_read().

## Essentially, if we get a bus error it checks the EPC value and if it

## is at the instruction that accesses the PCI bus, in hal_pci_config_read(),

## it skips it and fixes the registers to allow the program to continue.

## None of this would be necessary if the VRC4373 behaved sensibly and

## returned 0xFFFFFFFF for reads from empty device slots like it should.

        .text

        .globl  hal_bus_error_vsr

hal_bus_error_vsr:

        # We come here with everything still in registers and:

        # K0 = vector number (==7*4)

        # K1 = address of this routine

        # Check for special address

        la      k1,hal_pci_config_read_load

        mvafc0  k0,epc

        bne     k0,k1,1f

        nop

        # We have a match, skip the offending instruction

        # and put 0xFFFFFFFF into V0.

        # First we must clear the EXL bit so that we can

        # write to EPC.

        mfc0    k1,status               # Get status reg

        la      v0,0xFFFFFFFD           # mask for EXL

        and     k1,v0,k1                # clear EXL

        mtc0    k1,status               # return to CP0

        nop                             # let it work

        nop

        nop

        addi    k0,k0,4                 # skip offending instruction

        mvatc0  k0,epc                  # return to EPC

        nop                             # let it work

        nop

        nop

        la      v0,0xFFFFFFFF           # Put 0xFFFFFFFF into v0

        sync                            # let everything settle

        eret                            # and return

        nop

        # If this is not the special location, we need to continue

        # with the usual bus error handling. Since we no longer have

        # the original VSR table entry, we use the one just before it

        # (for instruction fetch bus error). At present this points

        # to the same error handler.

1:

        la      k1,hal_vsr_table        # Get VSR table

        lw      k1,24(k1)               # Pick another vector to follow

        la      k0,28                   # but pretend we are still Bus Error

        jr      k1                      # go there

        nop

##-----------------------------------------------------------------------------

## PCI config space access function

##

## This is the only function that should be used to read data from the PCI

## configuration space data register. It works with the bus error VSR

## above to work around any bus errors provoked by the VRC4373.

FUNC_START(hal_pci_config_read)

hal_pci_config_read_load:

        .set noreorder

        lw      v0,0(a0)        # Read the value. If this bus-errors the

                                # handler will skip this instruction and

                                # put 0xFFFFFFFF into v0.

        jr      ra              # And return

        nop

FUNC_END(hal_pci_config_read)

##-----------------------------------------------------------------------------

## Breakpoint springboard

## The following value has been determined by looking at the code that

## PMON puts in the interrupt vector. Clearly it will be different for

## different versions of PMON. A better approach might be to copy the original

## code out and execute that here. However, there is no guarantee that it is

## position independent.

#define CYGHWR_MIPS_PMON_EXEPTION_ENTRY 0xa0000dd4

        .text

        .globl hal_breakpoint_springboard

hal_breakpoint_springboard:

        # We enter here with all of the CPU state still

        # in its registers except:

        # K0 = vector index

        # K1 = address of this function

        la      k0,CYGHWR_MIPS_PMON_EXEPTION_ENTRY

        jr      k0

        nop

##-----------------------------------------------------------------------------

## ISR tables.

        .extern hal_default_isr

        .data

        .globl  hal_interrupt_handlers

hal_interrupt_handlers:

        .long   hal_default_isr

        .long   hal_isr_springboard

        .long   hal_isr_springboard

        .long   hal_isr_springboard

        .long   hal_default_isr

        .long   hal_default_isr

        .rept   32

        .long   hal_default_isr

        .endr

        .globl  hal_interrupt_data

hal_interrupt_data:

        .long   0

        .long   CYGHWR_HAL_MIPS_VRC4373_INTC_STAT0

        .long   CYGHWR_HAL_MIPS_VRC4373_INTC_STAT1

        .long   CYGHWR_HAL_MIPS_VRC4373_INTC_STAT2

        .long   0

        .long   0

        .rept   32

        .long   0

        .endr

        .globl  hal_interrupt_objects

hal_interrupt_objects:

        .rept   38

        .long   0

        .endr

        .globl  cyg_hal_interrupt_level

cyg_hal_interrupt_level:

        .rept   38

        .byte   0

        .endr

##-----------------------------------------------------------------------------

## MMU setup.

## Much of this code is taken from the PMON sources, hence it does not fully

## conform to our normal coding conventions.

#if defined(CYG_HAL_STARTUP_ROM) || defined(CYG_HAL_STARTUP_ROMRAM)

## DEFINITIONS FOR THE TLB SUPPORT

#define IO_PHYSICAL_BASE 0x80000000

#define IO_VIRTUAL_BASE  0xc0000000

#define NTLBENTRIES      32

#define K0BASE           0x80000000

#define TLBLO_G          0x00000001

#define TLBLO_V          0x00000002

#define TLBLO_D          0x00000004

#define TLBPGMASK_MASK   0x01ffe000

#define TLBINX_INXMASK   0x0000003f

#define CFG_C_UNCACHED   2

#define TLBLO_CSHIFT     3

#define TLBLO_PFNSHIFT   6

#define TLBLO_PFNMASK    0x3fffffc0

#define TLBHI_VPN2MASK  0xffffe000

#define TLBHI_VPN2SHIFT 13

#define TLBHI_VPNMASK   0xfffff000

#define TLBHI_VPNSHIFT  12

#define TLBLO_UNCACHED  (CFG_C_UNCACHED<

#define PAGE_SIZE       0x01000000

#define PADDR_INC       0x02000000

#define NUMB_PG         8

        .text

        .set noreorder

        .extern hal_mmu_setup_return

FUNC_START(hal_mmu_setup)

        mtc0    zero,tlbhi

        nop

        li      a0,0

2:

        bal     resettlb

        nop

        addiu   a0,a0,1

        bne     a0,NTLBENTRIES,2b

        nop

#define tlblo_even      s0

#define tlblo_odd       s1

#define vaddr           s2

#define paddr0          s3

#define paddr1          s4

#define pmask           s5

#define tmp             s6

#define ix              k1

        li      ix,0

        li      vaddr,IO_VIRTUAL_BASE

        li      paddr0,IO_PHYSICAL_BASE

loop:

        li      a0,((PAGE_SIZE - 1) << 1)

        li      a1,TLBPGMASK_MASK

        and     pmask, a0,a1

        li      tlblo_even, TLBLO_V | TLBLO_D | TLBLO_G

        li      tlblo_odd, TLBLO_V | TLBLO_D | TLBLO_G

        li      tmp,PAGE_SIZE

        addu    paddr1,paddr0,tmp

        li      tmp,TLBHI_VPN2MASK

        and     a1,vaddr,tmp

        li      tmp,TLBLO_PFNSHIFT

        srl     a2,paddr0,tmp

        li      tmp,TLBLO_PFNMASK

        and     a2,a2,tmp

        or      a2,a2,TLBLO_UNCACHED

        or      a2,a2,tlblo_even

        li      tmp,TLBLO_PFNSHIFT

        srl     a3,paddr1,tmp

        li      tmp,TLBLO_PFNMASK

        and     a3,a3,tmp

        or      a3,a3,TLBLO_UNCACHED

        or      a3,a3,tlblo_odd

        move    a0,pmask

        or      a0,a0,ix

        bal     map_tlb4000

        nop

        addi    ix,ix,1

        li      tmp,PADDR_INC

        addu    vaddr,vaddr,tmp

        addu    paddr0,paddr0,tmp

        li      tmp,NUMB_PG

        bne     ix,tmp,loop

        nop

        # Go back via a jump, not a return

        lar     k0,hal_mmu_setup_return

        jr      k0

        nop

FUNC_END(hal_mmu_setup)

## Invalidate the TLB entry specified by index

##

## resettlb(index)

##      a0  =  index

##

## Uses : t0, t2, v0, a0

FUNC_START(resettlb)

        li      t2,K0BASE & TLBHI_VPN2MASK

        mfc0    t0,tlbhi                # save current TLBHI

        mfc0    v0,status               # save SR and disable interrupts

        mtc0    zero,status             # clear interrupts

        mtc0    t2,tlbhi                # invalidate entry

        mtc0    zero,tlblo0

        mtc0    zero,tlblo1

        mtc0    a0,index

        nop; nop; nop; nop; nop; nop; nop; nop

        tlbwi

        nop; nop; nop; nop; nop; nop; nop; nop

        mtc0    t0,tlbhi

        mtc0    v0,status

        j       ra

        nop

FUNC_END(resettlb)

## Setup R4000 TLB entry

##

## map_tlb4000(mask_index, tlbhi, pte_even, pte_odd)

##      a0  =  TLB entry index and page mask

##      a1  =  virtual page number and PID

##      a2  =  pte -- contents of even pte

##      a3  =  pte -- contents of odd pte

##

##

##

## Uses : t0, t1, t2, v0, a0, a1, a2, a3

FUNC_START(map_tlb4000)

        and     t2,a0,TLBPGMASK_MASK

        and     a0,TLBINX_INXMASK

        mfc0    t1,tlbhi                # save current TLBPID

        mfc0    v0,status               # save SR and disable interrupts

        mtc0    zero,status             # clear interrupts

        mtc0    t2,pagemask             # set

        mtc0    a1,tlbhi                # set VPN and TLBPID

        mtc0    a2,tlblo0               # set PPN and access bits

        mtc0    a3,tlblo1               # set PPN and access bits

        mtc0    a0,index                # set INDEX to wired entry

        nop; nop; nop; nop; nop; nop; nop; nop

        tlbwi                           # drop it in

        nop; nop; nop; nop; nop; nop; nop; nop

        mtc0    t1,tlbhi                # restore TLBPID

        mtc0    v0,status               # restore SR

        j       ra

        nop

FUNC_END(map_tlb4000)

#endif

##-----------------------------------------------------------------------------

## MEMC initialization.

## This also initializes the PCI bus and ISA bus bridge, so at the end of this

## we should have full access to all the memory and devices we need.

## This code is table driven, which is somewhat more compact that coding it all.

## Table entries consist of an address and a value to store in that address.

## A zero address terminates the table. Two special address values modify the

## behaviour:

## DELAY_LOOP   loops for the number of iterations in the value field.

## WRITE16      treats the next 2 words as an address and value to be written

##              with a 16 bit write cycle.

#if defined(CYG_HAL_STARTUP_ROM) || defined(CYG_HAL_STARTUP_ROMRAM)

#define DELAY_LOOP      1

#define WRITE16         2

#define WRITEREAD32     3

FUNC_START(hal_memc_setup)

        lar     t0,hal_memc_setup_table

        la      t1,0xbfc00000

        la      t2,DELAY_LOOP

        la      t3,WRITE16

        la      t4,WRITEREAD32

1:

        lw      a0,0(t0)        # next table entry

        lw      a1,4(t0)        # value to write

        addiu   t0,8            # go to next entry

        beq     a0,t2,2f        # Check for delay

        nop

        beq     a0,t3,3f        # Check for 16 bit write

        nop

        beq     a0,t4,4f        # Check for 32 bit write/read

        nop

        beqz    a0,9f           # zero terminates loop

        nop

        lw      zero,0(t1)      # uncached read to flush write buffer

        sw      a1,0(a0)        # write it

        lw      zero,0(t1)      # uncached read to flush write buffer

        b       1b

        nop

4:

        lw      a3,0(t0)        # get next word

        addiu   t0,4            # skip it

        lw      zero,0(t1)      # uncached read to flush write buffer

        sw      a3,0(a1)        # write it

        lw      a3,0(a1)        # and read it back

        lw      zero,0(t1)      # uncached read to flush write buffer

        b       1b

        nop

2:

        lw      zero,0(t1)      # uncached read to flush write buffer

        bnez    a1,2b           # count down by value in a1

        addiu   a1,-1           # decrement in delay slot

        b       1b              # go back to loop

        nop

3:

        lw      a3,0(t0)        # get next word

        addiu   t0,4            # skip it

        sh      a3,0(a1)        # store halfword

        lw      zero,0(t1)      # uncached read to flush write buffer

        b       1b

        nop

9:

        jr      ra

        nop

FUNC_END(hal_memc_setup)

##-----------------------------------------------------------------------------

## Definitions for the VRC4373, also known as the Nile I,

## and maybe the Nile III as well.

#define N1_BASE         0xAF000000

#define N2_BASE         0xBC000000

#define BMCTRL         (N1_BASE + 0x00)

#define S1CTRL         (N1_BASE + 0x04)

#define S2CTRL         (N1_BASE + 0x08)

#define S3CTRL         (N1_BASE + 0x0C)

#define S4CTRL         (N1_BASE + 0x10)

#define PCIMSTRADDR1   (N1_BASE + 0x14)

#define PCIMSTRADDR2   (N1_BASE + 0x18)

#define PCISLAVADDR1   (N1_BASE + 0x1C)

#define PCISLAVADDR2   (N1_BASE + 0x20)

#define PCIMSTRIO      (N1_BASE + 0x24)

#define PCICNFGDATA    (N1_BASE + 0x28)

#define PCICNFGADDR    (N1_BASE + 0x2C)

#define PCIMBOX1       (N1_BASE + 0x30)

#define PCIMBOX2       (N1_BASE + 0x34)

#define DMACTRL1       (N1_BASE + 0x38)

#define DMALCLADDR1    (N1_BASE + 0x3C)

#define DMAPCIADDR1    (N1_BASE + 0x40)

#define DMACTRL2       (N1_BASE + 0x44)

#define DMALCLADDR2    (N1_BASE + 0x48)

#define DMAPCIADDR2    (N1_BASE + 0x4C)

#define BUSERRSTAT     (N1_BASE + 0x50)

#define INTCNTRL       (N1_BASE + 0x54)

#define REFRESHRATE    (N1_BASE + 0x58)

#define BOOTROMWPRTCT  (N1_BASE + 0x5C)

#define PCI_EXCL_ACC   (N1_BASE + 0x60)

#define PCI_ENABLE_REG (N1_BASE + 0x74)

#define N3_POM_INIT    (N1_BASE + 0x78)

/*

#define N1RESERVED1    (N1_BASE + 0x60)

*/

#if defined(CYGPKG_HAL_MIPS_VR4300_VRC4375)

#define N3_EM           (N1_BASE + 0x7C)

#define N3_ARB          (N1_BASE + 0x80)

#define UARTRBR         (N1_BASE + 0x84)

#define UARTTHR         (N1_BASE + 0x84)

#define UARTIER         (N1_BASE + 0x88)

#define UARTDLL         (N1_BASE + 0x84)

#define UARTDLM         (N1_BASE + 0x88)

#define UARTIIR         (N1_BASE + 0x8C)

#define UARTFCR         (N1_BASE + 0x8C)

#define UARTLCR         (N1_BASE + 0x90)

#define UARTMCR         (N1_BASE + 0x94)

#define UARTLSR         (N1_BASE + 0x98)

#define UARTMSR         (N1_BASE + 0x9C)

#define UARTSCR         (N1_BASE + 0xA0)

#endif

#define N1PCIHEADER    (N1_BASE + 0x100)

#define N1PCICMD       (N1PCIHEADER + 0x04)

#define MBOXPCIADDR    (N1PCIHEADER + 0x10)

#define N1CLSIZE       (N1PCIHEADER + 0x0c)  /* Cache Line Size */

#define N1MLTIM        (N1PCIHEADER + 0x0d)

#define N1MBADD        (N1PCIHEADER + 0x10)

#define N1RSVD2        (N1PCIHEADER + 0x40)  /* Word boundary */

#define N1RTYTIM       (N1PCIHEADER + 0x41)

##-----------------------------------------------------------------------------

## Definitions for the VRC4372, also known as the Nile II.

#if defined(CYGPKG_HAL_MIPS_VR4300_VRC4373)

#define PCI_N2_DEV              0x00010000      /* PCI Device # - Nile 2 */

#elif defined(CYGPKG_HAL_MIPS_VR4300_VRC4375)

#define PCI_N2_DEV              0x00080000      /* PCI Device # - Nile 2 */

#endif

#define N2CLSIZE                ( 0x0c)  /* Cache Line Size */

#define N2IOADD                 ( 0x14)

#define N2DSCTIM                ( 0x40)

#define IOCON             (N2_BASE + 0x0000)

  /* GPIO Bus   Controller Registers    */

#define GPDIR             (IOCON + 0x0100)

#define GPOUT             (IOCON + 0x0104)

#define GPIN              (IOCON + 0x0108)

  /* Interrupt  Controller Registers    */

#define INTPOL            (IOCON + 0x200)

#define INTTRIG           (IOCON + 0x204)

#define INTPINS           (IOCON + 0x208)

#define INTMASK0          (IOCON + 0x20C)

#define INTSTAT0          (IOCON + 0x210)

#define INTMASK1          (IOCON + 0x214)

#define INTSTAT1          (IOCON + 0x218)

#define INTMASK2          (IOCON + 0x21C)

#define INTSTAT2          (IOCON + 0x220)

  /* IO Bus     Controller Registers    */

#if defined(CYGPKG_HAL_MIPS_MSBFIRST)

// The 16 bit registers are swapped pairwise in each word.

#define IOPROF_00         (IOCON + 0x0402)

#define IOPROF_01         (IOCON + 0x0400)

#define IOPROF_02         (IOCON + 0x0406)

#define IOPROF_03         (IOCON + 0x0404)

#define IOPROF_04         (IOCON + 0x040A)

#define IOPROF_05         (IOCON + 0x0408)

#define IOPROF_06         (IOCON + 0x040E)

#define IOPROF_07         (IOCON + 0x040C)

#define IOPROF_08         (IOCON + 0x0412)

#define IOPROF_09         (IOCON + 0x0410)

#define IOPROF_0A         (IOCON + 0x0416)

#define IOPROF_0B         (IOCON + 0x0414)

#define IOPROF_0C         (IOCON + 0x041a)

#define IOPROF_10         (IOCON + 0x0422)

#define IOPROF_11         (IOCON + 0x0420)

#define IOPROF_12         (IOCON + 0x0426)

#define IOPROF_13         (IOCON + 0x0424)

#elif defined(CYGPKG_HAL_MIPS_LSBFIRST)

#define IOPROF_00         (IOCON + 0x0400)

#define IOPROF_01         (IOCON + 0x0402)

#define IOPROF_02         (IOCON + 0x0404)

#define IOPROF_03         (IOCON + 0x0406)

#define IOPROF_04         (IOCON + 0x0408)

#define IOPROF_05         (IOCON + 0x040A)

#define IOPROF_06         (IOCON + 0x040C)

#define IOPROF_07         (IOCON + 0x040E)

#define IOPROF_08         (IOCON + 0x0410)

#define IOPROF_09         (IOCON + 0x0412)

#define IOPROF_0A         (IOCON + 0x0414)

#define IOPROF_0B         (IOCON + 0x0416)

#define IOPROF_0C         (IOCON + 0x0418)

#define IOPROF_10         (IOCON + 0x0420)

#define IOPROF_11         (IOCON + 0x0422)

#define IOPROF_12         (IOCON + 0x0424)

#define IOPROF_13         (IOCON + 0x0426)

#else

#error MIPS endianness not define by configuration

#endif

#define IOTOUT            (IOCON + 0x0430)

#define IOPOL             (IOCON + 0x0434)

##-----------------------------------------------------------------------------

## PCI definitions

#define PCI_IOSPACE_BASE        0x0c            /* PCI I/O Space Adr */

#define PCIADR_REGNO    0x000000fc  /* Register # mask           */

#define PCI_CONFIG( dev, func, reg ) ( dev | ( reg  & PCIADR_REGNO) )

#define PCI_COMMAND_STATUS_REG          0x04

#define PCI_MAP_REG_START               0x10

#define PCI_INTERRUPT_REG               0x3c

##-----------------------------------------------------------------------------

## The initialization table

hal_memc_setup_table:

        .long   DELAY_LOOP,     0x00010000      # Wait for HW to settle

        # Set up SDRAM and SIMM1

#if defined(CYGPKG_HAL_MIPS_VR4300_VRC4373)

        .long   BMCTRL,         0x0000803b      # Base memory setup

        .long   S1CTRL,         0x0402013f      # SIMM1

#elif defined(CYGPKG_HAL_MIPS_VR4300_VRC4375)

        .long   N3_EM,          0x00000000

        .long   N3_ARB,         0x00000000

        .long   BMCTRL,         0x0000100b      # Base memory setup

        # Dont set up SIMMs on VR4375 at present.

#else

#error Unsupported board

#endif

        # Set up power-on memory state

        .long                   N3_POM_INIT,    0x00000002      # Power-on memory init

        .long   DELAY_LOOP,     0x00000100                      # wait a bit

        .long   WRITEREAD32,    N3_POM_INIT,    0x00000004      # Power-on memory init

        .long   DELAY_LOOP,     0x00000100                      # wait a bit

        .long   WRITEREAD32,    N3_POM_INIT,    0x00000001      # Power-on memory init

        .long   DELAY_LOOP,     0x00000100                      # wait a bit

        .long   REFRESHRATE,    0x00000fff                      # DRAM refresh rate

#if defined(CYGPKG_HAL_MIPS_VR4300_VRC4375)

        .long   N3_ARB,         0x00000005

#endif

        .long   BOOTROMWPRTCT,  0xffffff3e      # Write protect boot ROM

        # Set up PCI master address window

        .long   PCIMSTRADDR1,   0x1c0fd01c

        .long   PCIMSTRADDR2,   0x80081080

        # Set up PCI slave address window

        .long   PCISLAVADDR1,   0x00081000

        .long   PCISLAVADDR2,   0x10081080

        # Map PCI IO space Phys == Local

        .long   PCIMSTRIO,      0x0c0fd00c

        # VRC437X Bridge config space

        .long   N1PCICMD,       0x00000006      # Memory space enable, bus master

        .long   N1CLSIZE,       0x00003000      # Master latency time

        .long   N1MBADD,        0x20000000      # Mailbox base address

        .long   N1RSVD2,        0x0000f000      # Retry value

        .long   PCI_EXCL_ACC,   0x00000020      # PCI exclusive access register

        .long   PCI_ENABLE_REG, 0x00000005      # PCI config done, enable arbitration

        # Set up 4372. This is configured entirely through its PCI

        # configuration space. Hence the following all consist of

        # writing an address to the PCICNFGADDR register followed

        # by a write of the data to the PCICNFGDATA register.

        .long   PCICNFGADDR,    PCI_CONFIG( PCI_N2_DEV, 0, PCI_COMMAND_STATUS_REG)

        .long   PCICNFGDATA,    0x00000146

        .long   PCICNFGADDR,    PCI_CONFIG( PCI_N2_DEV, 0, N2CLSIZE)

        .long   PCICNFGDATA,    0x00003000

        .long   PCICNFGADDR,    PCI_CONFIG( PCI_N2_DEV, 0, PCI_MAP_REG_START)

        .long   PCICNFGDATA,    0x1c000000

        .long   PCICNFGADDR,    PCI_CONFIG( PCI_N2_DEV, 0, N2IOADD)

        .long   PCICNFGDATA,    0x80000000

        .long   PCICNFGADDR,    PCI_CONFIG( PCI_N2_DEV, 0, PCI_INTERRUPT_REG)

        .long   PCICNFGDATA,    0x00000000

        .long   PCICNFGADDR,    PCI_CONFIG( PCI_N2_DEV, 0, N2DSCTIM)

        .long   PCICNFGDATA,    0x0070f000

        # Set up IO bus controller chip select profile registers to

        # allow access to the devices.

        .long   WRITE16,        IOPROF_00,      0x04d1  # RTC - DS1386

        .long   WRITE16,        IOPROF_01,      0x007f  # DUART - Z8530

        .long   WRITE16,        IOPROF_02,      0x007f  # Timer - Z8536

        .long   WRITE16,        IOPROF_03,      0x00d9  # Parallel = 8255

        .long   WRITE16,        IOPROF_06,      0x007f  # 7 segment display

        .long   WRITE16,        IOPROF_07,      0x007f  # 7 segment display

        # Configure the rest of the 4372

        .long   IOTOUT,         0x200003c0      # IO timout control

        .long   IOPOL,          0x00000000      # IO bus pin polarity

        .long   GPDIR,          0x000007c0      # GPIO pins 6-10 output

        .long   INTPOL,         0x00003fff      # Interrupt polarity

        .long   INTTRIG,        0x00003fff      # Interrupt trigger

        .long   INTMASK0,       0x00000000

        .long   INTMASK1,       0x00000000

        .long   INTMASK2,       0x00000000

        .long   INTSTAT0,       0x00000000      # Zero all int status regs

        .long   INTSTAT1,       0x00000000

        .long   INTSTAT2,       0x00000000

        .long   DELAY_LOOP,     0x00010000      # Wait for HW to settle

        .long   0,              0

#endif

##-----------------------------------------------------------------------------

## end of platform.S